Dental sealant

Background

Dental caries is an upset of the balance between loss and gain of minerals from a tooth surface. The loss of minerals from our teeth occurs from the bacteria within our mouths fermenting foods and producing acids, whereas the tooth gains minerals from our saliva and fluoride that is present within our mouths. When this balance is skewed due to frequent intake of fermentable carbohydrates, poor oral hygiene and lack of fluoride consumption there is a continuous loss and little gain of minerals over a long period of time, which can ultimately cause what we know as tooth decay.

In our oral cavity, biting surfaces of back teeth are most susceptible to caries due to the presence of grooves & fissures which favours formation and retention of plaque.

Fissure sealants are a preventive treatment that is part of the minimal intervention dentistry approach to dental care. This approach facilitates prevention and early intervention, in order to prevent or stop the dental caries process before it reaches the ends stage of the disease, which is also known as the "hole" or cavitation of a tooth. Once the tooth is cavitated it requires a dental restoration in order to repair the damage, this emphasizes the importance of prevention in preserving our teeth for a lifetime of chewing.

Preventive treatment options for dental caries besides fissure sealants, involve promoting & education on toothbrushing technique with fluoride toothpaste, use of fluoride supplements & application of topical fluorides onto tooth surface.

The aim of fissure sealants is to prevent or arrest the development of dental caries. Preventing tooth decay from the pits and fissures of the teeth is achieved by the fissure sealants providing a physical barricade to protect natural tooth surfaces and grooves, inhibiting build-up of bacteria & food trapped within such fissures & grooves. Fissure sealants also provide a smooth surface that is easily accessible for both our natural protective factor, saliva and the toothbrush bristles when cleaning our teeth. Multiple oral health care professionals including a dentist, dental therapist, dental hygienist, an oral health therapist and dental assistants (in some states in the USA) are able to apply dental sealants to teeth.

Dental sealants are a plastic material placed in the pits and fissures (the recesses on the chewing surfaces) of primary (baby) or permanent (adult) molar & premolar teeth at the back of the mouth. These molar teeth are considered the most susceptible teeth to dental caries due to the anatomy of the chewing surfaces of these teeth, which unfortunately inhibits protection from saliva and fluoride and instead favours plaque accumulation.

History

There have been many attempts made within past decades to prevent the development of caries, in particular occlusal caries as it was once generally accepted that pits and fissures of teeth would become infected with bacteria within 10 years of erupting into the mouth. G.V. Black, the creator of modern dentistry, informed that more than 40% of caries incidences in permanent teeth occurred in pits and fissures due to being able to retain food and plaque.

One of the first attempts to prevent occlusal caries occurred as early as 1905 by Willoughby D. Miller. Miller, a pioneer of dentistry, was applying silver nitrate to surfaces of teeth, chemically treating the biofilm with its antibacterial functions against both Streptococcus mutans and Actinomyces naeslundii, which are both carious pathogens. Silver nitrate, which was also being practiced by H. Klein and J.W. Knutson in the 1940s, was being used in attempt to prevent and arrest occlusal caries.

In 1921, T.P. Hyatt, a pioneer researcher, was the first person to recommend prophylactic odontotomy (preventive operation). This procedure involved creating Class 1 cavity preps of teeth that were considered at risk of developing occlusal caries, which included all pits and fissures. The widening of the pits and fissures were then filled with amalgam.

C.F Bödecker, a dentist and researcher, also made attempts to prevent occlusal caries. Initially, in 1926 Bödecker would use a large round bur to smooth out the fissures. 1929, Bödecker attempted to prevent occlusal caries by cleaning the pit and fissures with an explorer and then sealing the pits and fissures with dental cement, such as oxyphosphate cement. Bödecker then later became an advocator for prophylactic odontotomy procedures (preventive operations).

It was in 1955, that M.G. Buonocore gave insight to the benefits of etching enamel with phosphoric acid. His studies demonstrated that resin could be bonded to enamel through acid etching, increasing adhesion whilst also creating an improved marginal integrity of resin restorative material. It was this bonding system that lead to the future successful creation of fissure sealants.

In 1966, E.I. Cueto created the first sealant material, which was methyl cyanoacrylate. However, this material was susceptible to bacterial breakdown over time, therefore was not an acceptable sealing material. Bunonocore made further advances in 1970 by developing bisphenol-a glycidyl dimethacrylate, which is a viscous resin commonly known as BIS-GMA. This material was used as the basis for many resin-based sealant/composite material developments in dentistry, as it is resistant to bacterial breakdown and forms a steady bond with etched enamel.

In 1974, glass ionomer cement fissure seals (GIC) were introduced by J.W. McLean and A.D. Wilson.

Modern sealant materials

Modern dental sealants generally are either resin based or glass ionomer based. Hybrid materials such as polyacid modified resin ("compomer") which lies between these two categories.

Resin based sealants

It is customary to refer to the development of resin based sealants in generations:

1. First generation: set with UV curing. They are no longer marketed.
2. Second generation: chemical-curing (autopolymerized).
3. Third generation: visible light-cured.
4. Fourth generation: contain fluoride.

As part of the wider debate over the safety of bisphenol A (BPA), concerns have been raised over the use of resin based sealants. BPA is a xenoestrogen, i.e. it mimics the relative bioactivity of estrogen, a female sex hormone. Pure BPA is rarely present in dental sealants, however they may contain BPA derivatives. There is very little research about the potential estrogen-like effects of BPA derivatives. A transient presence of BPA in saliva has been reported immediately following placement of some resin based sealants. The longest duration of salivary BPA was 3 hours after placement, so there is little risk of chronic low-dose BPA exposure. The currently available evidence suggests that there is no risk of estrogen-like side effects with resin based sealants. Several national dental organizations have published position statements regarding the safety of resin based dental materials, e.g. the American Dental Association, the Australian Dental Association, the British Dental Association, and the Canadian Dental Association.

Glass ionomer sealants

GIC materials bond both to enamel and dentine after being cleaned with polyacrylic acid conditioner. Some other advantages GIC’s have is that they contain fluoride and are less moisture sensitive, with suggestions being made that despite having poor retention, they may prevent occlusal caries even after the sealant has fallen out due to their ability to release fluoride.

Resin based sealants versus Glass ionomer sealants

It was shown that GIC materials were more effective in prevention of development of caries despite the higher non-successful rate compared to resin based sealants. This may be accounted for due to the fluoride-releasing property of GIC which increases salivary fluoride level that may aid in preventing dental caries.

Resin-based sealants are normally the preferred choice of material for denture sealants. GIC material may be used as a provisional protective material when there are concerns regarding adequate moisture control.

Effectiveness

Sealants are accepted as an effective preventive method for caries, and as long as the sealant remains adhered to the tooth, cavities can be prevented. It is for this reason that sealant success is now measured by the length of time a sealant remains on the tooth, rather than the decay experienced in sealed and unsealed teeth. The ability of a pit and fissure sealant to prevent dental caries is highly dependent on its ability to retain on the tooth surface.

It has been demonstrated that use of adhesive systems before applying dental sealants may improve retention. Traditional retention of a sealant on tooth surface is through acid etching.

The most common reason for sealant failure is salivary contamination during sealing placement. Other factors include clinician inexperience, lack of client co-operation, and less effective sealant material used.

Sealants may be in conjunction with fluoride varnish as a preventive method which is shown to be significantly more successful than fluoride varnish alone.

Various factors can help contribute to the retention of fissure sealants. These include:

Longevity

Although sealants do wear naturally and may become damaged over time, they have the potential to remain effective for five years or longer, despite the heavy pressures endured by teeth during chewing each day. Longevity of the dental sealants is also dependent on the type of material used for the fissure sealant. It is not uncommon for fissure sealants to be retained into adulthood. It is believed that bacteria and food particles may eventually become entrapped under the dental sealants, and can thus cause decay in the very teeth intended to be protected. Fissure sealants are inspected during routine dental visits to ensure that they are retained in the fissures of the teeth. One of the major causes to the loss of sealants in the first year is salivary contamination.

On the basis of limited evidence both GIC and resin materials are equally acceptable in caries prevention, however retention rates between GIC and Resin have been shown to differ. Resin has been shown to be the superior product for retention. A 2-year clinical trial comparing GIC and Resin for fissure sealants demonstrated that the GIC had a total loss rate of 31.78%, in contrast to the resin which had a total loss rate of 5.96% The study did acknowledge that GIC had its therapeutic advantages other than retention, this included the benefit of fluoride release and its use on partially erupted teeth. Though GIC has poorer retention rates, the fact that they release active fluoride in the surrounding enamel is very important. They can exert a cariostatic effect and increased release of fluoride, and for these reasons GIC is more of a fluoride vehicle rather than a traditional fissure sealant. All three materials are as effective as each other if the correct techniques are used to complete the procedure.

Indications and contraindications

Indications for the use of dental sealants are individual patients or teeth that are at high risk of dental caries.

This includes patients with:

Contraindications for the use of dental sealants are individual patients or teeth that are at a low risk of dental caries:

This includes patients with:

Clinical procedure

The exact technique is dependent upon the material used and good application technique will increase retention of sealants which means sealants can last longer on the teeth. Generally, each quadrant is treated separately by using four-handed technique with an assistant and to follow the manufacturer’s recommendations. The patients should wear safety glasses for protection from chemicals and curing light. Once the patient is prepared, the surface of the tooth must be cleaned to allow maximum contact of the etch and the dental sealant with the enamel surface. A rubber dam may be used to prevent saliva from contaminating the intended site to be sealed, although often these are not used, especially for younger children. Moisture control is more of an issue with resin based sealants than with glass ionomer sealants. The surface is cleaned and dried.

Resin sealants require an phosphoric acid solution ("etch") to create microscopic porosity into which the sealant material can flow thereby increasing retention, increasing surface area and improving the strength of the bond between the sealant and the tooth surface. Etching time varies from 15-60 second depending on the product. After that, the tooth must be rinsed and dried thoroughly for 15–20 seconds. Chalky appearance on the dried tooth means the tooth has been properly etched. If the tooth does not have this chalky appearance, the etching process must be repeated. The sealant is then applied to the tooth and either set with a curing light or left to dry by itself. Compared to a typical dental filling, where an injection of local anesthetic and use of a dental drill may be involved, fissure sealants are quick and painless. The sealant material is carefully placed into the prepared pits and fissures by using a disposable instrument provided by the manufacturer. Overfilling on the tooth should be prevented to minimize occlusal adjustment. The material is left for 10 seconds after the placement prior to curing to allow optimum penetration of the sealant materials into the pores created by the etching procedure. Usually, curing is 20–30 seconds. Glass ionomer do not require light curing, however they will set faster with the usage of a curing light.

Resin-based sealants require an absolutely dry surface until polymerization is complete, so it is essential to avoid salivary contamination of the sealant site. A rubber dam or cotton roll isolation technique can be used to isolate the sealant site from saliva which is the common reason for sealant failure. Glass ionomer sealants have the advantage of not needing a dry field to be effective. In fact, the application procedure for glass ionomers can involve pressing a saliva-moistened finger onto the occlusal surface to push the sealant material into the pits and fissures.